DE102013113357A1 - Valve - Google Patents

Abstract

The invention relates to a valve (1) having a housing (2) with a valve chamber (3), with an inlet opening (5) and with a drain opening (6), with an adjustable valve element (4) which is located in the housing (2). is rotatably adjustable, wherein a damping element (12) is provided, which receives the valve element (4) radially outward and causes a damping of the adjustment of the valve element (4), wherein the damping of the damping element (12) is adjustable.

Description

The invention relates to a valve, in particular for switching or controlling a fluid flow.

Fluid flows are used in particular in motor vehicles, for example, to cool the engine or other units or to operate, for example, an air conditioner. Also, fluid streams are used to heat aggregates or the passenger compartment. Since the need for cooling the heater depends on the operating point of the vehicle, valves for switching or controlling the fluid flows in a motor vehicle have become known in the art.

These valves allow control of fluid flow, often requiring operating point dependent control of the valves.

Therefore, it is the object of the present invention to provide a valve which has operating point-dependent controllable properties in order to achieve an individual controllability of a fluid flow.

The object is achieved with the features of claim 1.

An embodiment of the invention relates to a valve having a housing with a valve chamber, with an inlet opening and with a drain opening, with an adjustable valve element, which is received rotatably adjustable in the housing, wherein a damping element is provided which receives the valve element radially outward and a Damping causes the adjustment of the valve element, wherein the damping of the damping element is adjustable. As a result, a simple, yet effective construction is achieved because the controllability of the damping element operating point-dependent, the behavior of the valve can be adjusted.

It is advantageous if the valve element is rotatably received in the housing. As a result, a rotary valve is provided, which has good sealing properties due to the rotatability of the valve element.

It is also advantageous if the valve element is a ring element which rests in the housing on a sealing surface for closing the valve in the radial direction and / or in the circumferential direction.

Furthermore, it is advantageous if a drive element is provided, which serves for the displacement of the valve element.

According to the invention it is advantageous if the drive element has a pressure chamber, which can be acted upon, wherein in the pressure chamber or adjacent to this a displaceable element is provided, which is displaced depending on the application and which is coupled to the valve element. Thus, a pressure medium is easy to carry out.

It is advantageous if the displaceable element is axially displaceable and a slotted guide is provided which converts the axial displacement of the displaceable element in a rotational movement of the valve element.

It is advantageous according to an embodiment, when the displaceable element is or has a membrane or a piston.

According to the invention it is expedient if the damping element has a housing with two chambers arranged therein, wherein a piston is provided in the housing, which is fixed to the housing, wherein the housing is connected to the displaceable element and displaced by displacement of the displaceable element.

It when the valve element is connected by means of the housing of the damping element and the slotted guide with the displaceable element is particularly advantageous.

It is advantageous if the piston is received displaceably relative to the housing, wherein the housing is connected to the valve element via the slotted guide.

It is also expedient if an opening or a gap for the flow of fluid between the one chamber into the other chamber is provided between the two chambers.

It is also advantageous if the fluid is a magnetorheological fluid.

It is expedient if the damping element has a magnet, in which the magnetic field is adjustable.

In the following the invention will be explained in detail by means of an embodiment with reference to the drawing. In the drawing shows:

1 a perspective view of a first embodiment of a valve according to the invention,

2 a perspective view of a second embodiment of the valve according to the invention,

3 a perspective view of a third embodiment of the valve according to the invention,

4 a view of the valve after 3 in another operating position,

5 a sectional view of a section of a valve,

6 a perspective view of a portion of a valve with a rotatable valve element,

7 a rotatable valve element,

8th a view of a valve with a rotatable valve element in a first operating position,

9 a view of a valve with a rotatable valve element in a second operating position,

10 a view of a valve with a rotatable valve element in a third operating position,

11 a view of the rotatable valve element according to 8th in a first operating position,

12 a view of the rotatable valve element according to 9 in a second operating position,

13 a view of the rotatable valve element according to 10 in a third operating position,

14 a view of a rotatable valve element in a first operating position, and

15 a view of a rotatable valve element in a second operating position.

The 1 to 4 show various embodiments of a valve according to the invention 1 in different views and in two different operating positions.

The valve 1 has a housing 2 which is essentially cylindrical. In the case 2 is an advantageous cylindrical valve chamber 3 formed, which is a rotatable valve element 4 receives.

The housing 2 also has an inlet opening 5 and a drain hole 6 these can also be reversed, so that then corresponding to the inlet opening 6 and the drain hole 5 would.

The valve element 4 is designed as a ring element hollow cylindrical and can in the housing 2 to be twisted. To control the flow of fluid through the valve 1 from the inlet opening 5 to drain opening 6 serves the valve element 4 , which is in the closed operating position of the valve 1 on a sealing surface 7 with its barrel-like outer surface creates. In the barrel-like outer surface is an opening that must correspond with the opening of the sealing surface to the valve 1 to open.

The valve element 4 is designed as a rotatable ring member which is radially inward on a sleeve 10 sits and is rotatably mounted on this. For this purpose, between the sleeve and the radially inner region of the ring element is a slotted guide 9 provided, which leads to that in lateral displacement of the sleeve 10 the valve element 4 is twisted.

The sleeve 10 is laterally displaceable and with the displacement of the sleeve 10 in the case 2 in a related inclusion, also the valve element 4 twisted. This puts the sleeve 10 the housing 11 a damping element 12 which will be described later.

To shift the sleeve 10 and thus also the valve element is a drive element 13 provided which displaces the sleeve with appropriate control. In 1 is the driving element 13 a piston-cylinder unit 14 with a cylinder 15 and a piston received therein 16 , wherein the piston may also be formed as a membrane. The cylinder 15 is beneficial in a chamber 17 or in two chambers 17 . 18 , please refer 2 , subdivided, wherein at least one of the chambers is druckmittelbeaufschlagbar for displacing the piston 16 , With the piston 16 is the sleeve 10 connected to the displacement of the piston 16 is also displaced axially.

In the sleeve 10 is another piston 19 provided, which together with the sleeve 10 as a housing, the damping element 12 forms. The piston 19 is by means of the piston rod 22 with the housing 2 of the valve 1 rigidly connected. The piston 19 divides the interior of the sleeve into two chambers 20 . 21 , Wherein their volume when displacing the sleeve 10 vary. In the chambers 20 . 21 is recorded a magnetorheological fluid, which in terms of its viscosity by means of the magnet 23 is controllable. If a magnetic field is applied, the viscosity of the fluid is reduced. This allows the fluid to provide more or less resistance to pass over an overflow or overflow gap between the chambers 20 . 21 to stream.

In 1 the sleeve shifts 10 against the restoring force of the spring 24 ,

In 2 is the spring 14 of the 1 not necessarily provided because the two pressure chambers 17 . 18 provide as chambers the provision of the piston by means of pressure medium. Nevertheless, the spring may additionally be provided. she is in 3 but not shown.

The 3 and 4 shows an alternative embodiment of the valve according to the invention 1 in which the drive element is a piston 16 having. Will the pressure chamber 26 and / or the pressure chamber 27 pressurized, for example, with negative pressure or pressure, so the piston can 16 axially displace and the associated sleeve 10 relocate. The feather 28 is between the case 2 or with one with the housing 2 axially fixed valve element 4 and the piston supported.

In 4 is the sleeve 10 further shifted to the right than in 3 , This causes a stronger rotation of the valve element 4 opposite to the position of 3 ,

The 5 show the arrangement of the piston 19 relative to the two chambers 20 . 21 , The fluid can be displaced when the piston 19 through a gap between the piston and the inner wall of the sleeve 10 flow past.

The 6 shows a schematic representation of parts of the valve 120 with a lid 121 as a housing part, a rotatable valve element 122 and an element with slotted guide 123 , The element 123 puts the sleeve 10 This has a piston arranged within a cylinder space, which by means of the piston rod 127 is fixable, the housing 124 of the element 123 against the force of the energy store 125 is displaceable in the axial direction.

With the housing 124 is the valve element 122 via an actuating means 128 connected, in the spiral gate guide 126 can engage, the valve element 122 in the axial direction firmly in the housing 121 is arranged, wherein upon displacement of the housing 124 of the element 123 due to the intervention in the slotted guide 126 the valve element 122 is twisted. Thus, fluid flows can be controlled, in which the valve element 122 Inlet and / or outlet openings in the valve housing 2 of the valve 1 can open or close to be able to control a targeted flow through the valve can.

The 7 shows a valve element 130 in a perspective view. The valve element 130 is as a cylindrical component with a cylindrical outer wall 131 and with a radially inwardly disposed hollow cylindrical receptacle 132 formed for the housing of the element. Also, the valve element has a radially oriented end wall 133 on. For fluid control are in the cylindrical outer wall 131 as well as in the front wall 133 openings 134 . 135 educated. The openings 134 extend over part of the circumference of the outer wall and are through a central web 136 separated from each other. The openings 135 are formed either circular or kidney-shaped and extend over part of the circumferential extent of the end wall.

The 8th to 10 show a spherical segment-like valve element 140 in a valve housing 141 in each case another operating position. In this case, the valve element 140 in each case a different angular position relative to the valve housing 141 on. The 11 to 13 show the position of the valve element 140 together with the position of the actuator and the energy accumulator for the positions according to the 8th to 10 ,

In the 8th to 10 is with 142 a fluid inlet partially shown and with 143 the fluid outlet. At the position of the valve element 140 according to 8th locks the valve element with its upper wall 144 the fluid inlet.

In 9 the valve element is twisted about 45 ° upwards so that the openings 145 in the range of fluid inlet 142 and fluid outlet 143 are arranged and thus a fluid communication between the fluid inlet 142 and fluid outlet 143 is possible.

In 10 In turn, the valve element is further turned upwards about 45 °, leaving the openings 145 in the area of the fluid inlet 142 are arranged. But this is the fluid outlet through the wall 144 blocked. This is a fluid communication between fluid inlet 142 and fluid outlet 143 not possible.

The 11 to 13 show the respective position of the valve element 140 according to the position of 8th to 10 , at 11 is the actuator 146 arranged to the left, the shift towards the energy storage 147 is low. Due to the position of the actuator 146 with his backdrop guide 148 stands the valve element 140 so that the openings 145 point forward and open the fluid outlet, with the wall 144 which faces upwards, blocks the fluid inlet.

at 12 is the actuator 146 arranged approximately centrally, the displacement in the direction of the energy storage 147 is partially completed. Due to the position of the actuator 146 with his backdrop guide 148 stands the valve element 140 so that the openings 145 partially forward and upward and open the fluid outlet and the fluid inlet. This allows fluid communication between the fluid inlet and the fluid outlet.

at 13 is the actuator 146 arranged right, the shift towards the energy storage 147 is almost completed. Due to the position of the actuator 146 with his backdrop guide 148 stands the valve element 140 so that the openings 145 point upwards and release the fluid inlet, while the forward wall 144 blocks the fluid outlet. Thus, no fluid communication between the fluid inlet and fluid outlet is possible.

The 14 and 15 show as a valve element 150 a disk 151 , which on a housing wall 152 the valve housing is rotatably arranged. Both the valve element 150 as well as the housing wall have openings 153 . 154 on that in 14 are not in overlap, so the valve is closed. In 15 are the openings 153 . 154 in overlap and the valve is open. The openings 153 . 154 are formed like a circle segment. Advantageously, other geometries could be used.

LIST OF REFERENCE NUMBERS

1

Valve

2

casing

3

valve chamber

4

valve element

5

inlet opening

6

drain hole

7

sealing surface

8th

end

9

link guide

10

shell

11

casing

12

damping element

13

driving element

14

Piston-cylinder unit

15

cylinder

16

piston

17

chamber

18

chamber

19

piston

20

chamber

21

chamber

22

piston rod

23

magnet

24

feather

26

 pressure chamber

27

pressure chamber

28

feather

120

Valve

121

 cover

122

valve element

123

 actuator

124

casing

125

power storage

126

 link guide

127

actuating means

130

valve element

131

 outer wall

132

admission

133

end wall

134

opening

135

opening

136

web

140

 valve element

141

valve housing

142

fluid inlet

143

fluid outlet

144

wall

145

opening

146

actuator

147

power storage

148

link guide

150

valve element

151

disc

152

housing

153

opening

154

opening

Claims (13)

Valve ( 1 ) with a housing ( 2 ) with a valve chamber ( 3 ), with an inlet opening ( 5 ) and with a drain opening ( 6 ), with an adjustable valve element ( 4 ), which in the housing ( 2 ) is received rotatably adjustable, wherein a damping element ( 12 ) is provided, which the valve element ( 4 ) receives radially on the outside and a damping of the adjustment of the valve element ( 4 ), wherein the damping of the damping element ( 12 ) is adjustable. Valve according to claim 1, characterized in that the valve element ( 4 ) in the housing ( 2 ) is received rotatably. Valve according to claim 1 or 2, characterized in that the valve element ( 4 ) is a ring element, which in the housing ( 2 ) on a sealing surface ( 7 ) for closing the valve in the radial direction and / or in the circumferential direction applies. Valve according to claim 1, 2 or 3, characterized in that a drive element ( 13 ) is provided, which of the displacement of the valve element ( 4 ) serves. Valve according to claim 4, characterized in that the drive element ( 13 ) a pressure chamber ( 17 . 18 ), which can be acted upon, wherein in the pressure room ( 17 . 18 ) or adjacent to this a displaceable element ( 16 ) is provided, which is displaced depending on the application and which with the valve element ( 4 ) is coupled. Valve according to claim 5, characterized in that the displaceable element is axially displaceable and a slotted guide ( 9 ) is provided, which converts the axial displacement of the displaceable element in a rotational movement of the valve element. Valve according to claim 5 or 6, characterized in that the displaceable element is a piston ( 16 ) or has one. Valve according to one of the preceding claims, characterized in that the damping element ( 12 ) a housing ( 11 ) with two chambers ( 20 . 21 ), wherein a piston ( 19 ) is provided in the housing, which is arranged fixed to the housing, wherein the housing ( 11 ) with the displaceable element ( 16 ) and is displaced by displacement of the displaceable element. Valve according to one of the preceding claims, characterized in that the valve element ( 4 ) by means of the housing ( 11 ) of the damping element ( 12 ) and the slotted guide with the displaceable element ( 16 . 25 ) connected is. Valve according to claim 8 or 9, characterized in that the piston ( 16 ) relative to the housing ( 11 ) is displaceable, wherein the housing ( 11 ) with the valve element ( 4 ) is connected via the slotted guide. Valve according to claim 8, 9 or 10, characterized in that between the two chambers ( 20 . 21 ) is provided an opening or a gap for the flow of a fluid between the one chamber into the other chamber. Valve according to one of the preceding claims, characterized in that the fluid is a magnetorheological fluid. Valve according to one of the preceding claims, characterized in that the damping element ( 12 ) a magnet ( 23 ), in which the magnetic field is adjustable.

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